Fusing Imperfect Photonic Cluster States

TL;DR

This paper investigates how decoherence impacts the construction of large photonic cluster states for quantum computing, analyzing the effects of imperfect primitives, fusion failures, and photon loss on the fidelity of the resulting clusters.

Contribution

It introduces a detailed analysis of decoherence effects on photonic cluster state construction, including strategies to optimize fidelity amid fusion failures and photon loss.

Findings

Decoherence of primitive clusters reduces overall fidelity.

Fusion failure probabilities significantly affect cluster quality.

Photon loss impacts the scalability of photonic cluster states.

Abstract

The ability to construct large photonic cluster states capable of supporting universal quantum computation relies on fusing together cluster primitives. These fusion operations are probabilistic and the efficiency of the construction process relies on recycling remains of cluster primitives that have undergone failed fusion attempts. Here I consider the effects of the inevitible decoherence that must arise while storing cluster primitives. First, I explore the case where dephased two-qubit cluster states are the basic resource for the construction of all larger cluster states, all fusion operations are successful, and no further dephasing occurs during the construction process. This allows us to explore how decoherence of the most basic, primitive clusters translate into imperfections of the larger cluster states constructed from them. I then assume that decoherence occurs before every attempted fusion operation and determine the best way to build a five qubit cluster. This requires including the effects of the fusion operation failures. Fidelity is used as the measure of accuracy for the constructed cluster states. Finally, I include a short discussion of photon loss and how it affects the construction of simple photonic clusters.